Tissue Engineered Bio-Blood-Vessel using a Tissue Specific Bioink and 3D Coaxial Cell Printing Technique: A Novel Therapy for Ischemic Disease

Abstract

Endothelial progenitor cells (EPCs) are a promising cell source for the treatment of several ischemic diseases for their potentials in neovascularization. However, the application of EPCs in cell-based therapy has shown low therapeutic efficacy due to hostile tissue conditions after ischemia. In this study, a bio-blood-vessel (BBV) is developed, which is produced using a novel hybrid bioink (a mixture of vascular-tissue-derived decellularized extracellular matrix (VdECM) and alginate) and a versatile 3D coaxial cell printing method for delivering EPC and proangiogenic drugs (atorvastatin) to the ischemic injury sites. The hybrid bioink not only provides a favorable environment to promote the proliferation, differentiation, and neovascularization of EPCs but also enables a direct fabrication of tubular BBV. By controlling the printing parameters, the printing method allows to construct BBVs in desired dimensions, carrying both EPCs and atorvastatin-loaded poly(lactic-co-glycolic) acid microspheres. The therapeutic efficacy of cell/drug-laden BBVs is evaluated in an ischemia model at nude mouse hind limb, which exhibits enhanced survival and differentiation of EPCs, increased rate of neovascularization, and remarkable salvage of ischemic limbs. These outcomes suggest that the 3D-printed ECM-mediated cell/drug implantation can be a new therapeutic approach for the treatment of various ischemic diseases.